Integrative
            <i>in vivo</i>
            analysis of the ethanolamine utilization bacterial microcompartment in
            <i>Escherichia coli</i>

Bacterial microcompartments (BMC) are protein organelles with diverse metabolic capabilities. Their functional diversity is determined by an enzymatic core that is sequestered within a structurally conserved protein shell architecture. Segregation of protein cargo into the BMC is enabled by encapsulation peptides (EPs), which are short helical domains fused to core proteins through a disordered linker. Here, we investigate how EPs drive multicomponent cargo assembly into biomolecular condensates. In vitro experiments supported by molecular dynamics simulations demonstrate the importance of both conserved hydrophobic packing and electrostatic interactions in stabilizing trimeric EP bundles. Topological rearrangements of EP domains can drive programmable liquid- or gel-like partitioning in vitro and in vivo. This partitioning is found to be EP-specific, modular and can co-assemble at least three fluorescent reporters. In summary, we describe the molecular features necessary to drive biomolecular condensation using a widespread peptide tag. This work can serve as a blueprint for implementing EP biotechnology across diverse applications.

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Bacterial microcompartment utilization in the human commensal Escherichia coli Nissle 1917

Clare,

Rutter,

Fedorec

et al. 2024

J Bacteriol

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Bacterial microcompartments (BMCs) are self-assembled protein structures often utilized by bacteria as a modular metabolic unit, enabling the catalysis and utilization of less common carbon and nitrogen sources within a self-contained compartment. The ethanolamine (EA) utilization (eut) BMC has been widely demonstrated in enteropathogens, such as Salmonella enterica , and current research is exploring its activity in the commensal species that populate the human gut. Escherichia coli Nissle 1917 (EcN) is a strong colonizer and probiotic in gut microbial communities and has been used extensively for microbiome engineering. In this study, the utilization of ethanolamine as a sole carbon source and the formation of the eut BMC in EcN were demonstrated through growth assays and visualization with transmission electron microscopy. Subsequently, flux balance analysis was used to further investigate the metabolic activity of this pathway. It was found that not only is the utilization of the eut BMC for the degradation of EA as a carbon source in EcN comparable with that of Salmonella enterica but also that ammonium is released into solution as a byproduct in EcN but not in S. enterica . Control of EA-dependent growth was demonstrated using different concentrations of the operon inducer, vitamin B 12 . We show that vitamin B 12 -dependent EA utilization as the sole carbon source enables growth in EcN, and demonstrate the concurrent formation of the BMC shell and inducible control of the eut operon. IMPORTANCE The human gut is a complex environment of different bacterial species, nutrient sources, and changing conditions that are essential for human health. An imbalance can allow for the emergence of opportunistic pathogens. Bacterial microcompartments (BMCs) are utilized by bacteria to metabolize less common nutrients, conferring a growth advantage. Although widely studied in enteropathogens, there is limited research on BMC activity in commensal species. We demonstrate the formation of the eut BMC and utilization of ethanolamine as a carbon source in the human gut commensal Escherichia coli Nissle 1917 (EcN). Additionally, we found increased ammonium production when EcN utilized ethanolamine but did not see the same in Salmonella enterica , highlighting potential differences in how these species affect the wider microbial community.

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Integrative in vivo analysis of the ethanolamine utilization bacterial microcompartment in Escherichia coli

Cited by 3 publications

References 98 publications

Engineering microbial cell factories by multiplexed spatiotemporal control of cellular metabolism: Advances, challenges, and future perspectives

Engineering microbial cell factories by multiplexed spatiotemporal control of cellular metabolism: Advances, challenges, and future perspectives

A blueprint for biomolecular condensation driven by bacterial microcompartment encapsulation peptides

Bacterial microcompartment utilization in the human commensal Escherichia coli Nissle 1917

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